Nested OBject manipulations
JSON is a very popular format for nested data exchange, and Object Relational Mapping (ORM) is a popular method to help developers make sense of large JSON objects, by mapping objects to the data. In some cases however, the nesting can be very deep, and difficult to map with objects. This is where nob can be useful: it offers a simple set of tools to explore and edit any nested data (Python native dicts and lists).
For more, checkout the home page, or play around with the library in colab:
[](https://colab.research.google.com/github/weiji14/deepbedmap/]
nob.Nob
objects can be instantiated directly from a Python dictionary:
t = Nob({
'key1': 'val1',
'key2': {
'key3': 4,
'key4': {'key5': 'val2'},
'key5': [3, 4, 5]
},
'key5': 'val3'
})
To create a Nob
from a JSON (or YAML) file, simply read it and feed the data
to the constructor:
import json
with open('file.json') as fh:
t2 = Nob(json.load(fh))
import yaml
with open('file.yml') as fh:
t3 = Nob(yaml.load(fh))
Similarly, to create a JSON (YAML) file from a tree, you can use:
with open('file.json', 'w') as fh:
json.dump(t2[:], fh)
with open('file.yml', 'w') as fh:
yaml.dump(t3[:], fh)
The variable t
now holds a tree, i.e the reference to the actual data. However,
for many practical cases it is useful to work with a subtree. nob
offers a useful
class NobView
to this end. It handles identically for the most part as the main tree,
but changes performed on a NobView
affect the main Nob
instance that it is linked
to. In practice, any access to a key of t
yields a NobView
instance, e.g.:
tv1 = t['/key1'] # NobView(/key1)
tv2 = t['key1'] # NobView(/key1)
tv3 = t.key1 # NobView(/key1)
tv1 == tv2 == tv3 # True
Note that a full path '/key1'
, as well as a simple key 'key1'
are valid
identifiers. Simple keys can also be called as attributes, using t.key1
.
To access the actual value that is stored in the nested object, simply use the [:]
operator:
tv1[:] >>> 'val1'
t.key1[:] >>> 'val1'
To assign a new value to this node, you can do it directly on the NobView instance:
t.key1 = 'new'
tv1[:] >>> 'new'
t[:]['key1'] >>> 'new'
Of course, because of how Python variables work, you cannot simply assign the value to
tv1
, as this would just overwrite it's contents:
tv1 = 'new'
tv1 >>> 'new'
t[:]['key1'] >>> 'val1'
If you find yourself with a NobView
object that you would like to edit directly,
you can use the .set
method:
tv1 = t.key1
tv1.set('new')
t[:]['key1'] >>> 'new'
Because nested objects can contain both dicts and lists, integers are sometimes needed as keys:
t['/key2/key5/0'] >>> NobView(/key2/key5/0)
t.key2.key5[0] >>> NobView(/key2/key5/0)
t.key2.key5['0'] >>> NobView(/key2/key5/0)
However, since Python does not support attributes starting with an integer, there is no attribute support for lists. Only key access (full path, integer index or its stringified counterpart) are supported.
In a simple nested dictionary, the access to 'key1'
would be simply done with:
nested_dict['key1']
If you are looking for e.g. key3
, you would need to write:
nested_dict['key2']['key3']
For deep nested objects however, this can be a chore, and become very difficult to
read. nob
helps you here by supplying a smart method for finding unique keys:
t['key3'] >>> NobView(/key2/key3)
t.key3 >>> NobView(/key2/key3)
Note that attribute access t.key3
behaves like simple key access t['key3']
. This
has some implications when the key is not unique in the tree. Let's say e.g. we wish
to access key5
. Let's try using attribute access:
t.key5 >>> KeyError: Identifier key5 yielded 3 results instead of 1
Oups! Because key5
is not unique (it appears 3 times in the tree), t.key5
is not
specific, and nob
wouldn't know which one to return. In this instance, we have
several possibilities, depending on which key5
we are looking for:
t.key4.key5 >>> NobView(/key2/key4/key5)
t.key2['/key5'] >>> NobView(/key2/key5)
t['/key5'] >>> NobView(/key5)
There is a bit to unpack here:
key5
is unique in the NobView
t.key4
(and key4
is itself
unique), so t.key4.key5
finds it correctly.key2
is unique, but key5
is still not unique to t.key2
.
There is not much advantage compared to a full path access t['/key2/key5']
.Paths: any Nob
(or NobView
) object can introspect itself to find all its valid paths:
t.paths >>> [Path('/'),
Path('/key1'),
Path('/key2'),
Path('/key2/key3'),
Path('/key2/key4'),
Path('/key2/key4/key5'),
Path('/key2/key5'),
Path('/key2/key5/0'),
Path('/key2/key5/1'),
Path('/key2/key5/2'),
Path('/key5')]
Find: in order to easily search in this path list, the .find
method is available:
t.find('key5') >>> [Path('/key2/key4/key5'),
Path('/key2/key5'),
Path('/key5')]
The elements of these lists are not strings, but Path
objects, as described
below.
Iterable: any tree or tree view is also iterable, yielding its children:
[tv for tv in t.key2] >>> [NobView(/key2/key3),
NobView(/key2/key4),
NobView(/key2/key5)]
Copy: to make an independant copy of a tree, use its .copy()
method:
t_cop = t.copy()
t == t_cop >>> True
t_cop.key1 = 'new_val'
t == t_cop >>> False
A new standalone tree can also be produced from any tree view:
t_cop = t.key2.copy()
t_cop == t.key2 >>> True
t_cop.key3 = 5
t_cop == t.key2 >>> False
All paths are stored internally using the nob.Path
class. Paths are full
(w.r.t. their Nob
or NobView
), and are in essence a list of the keys
constituting the nested address. They can however be viewed equivalently as
a unix-type path string with /
separators. Here are some examples
p1 = Path(['key1'])
p1 >>> Path(/key1)
p2 = Path('/key1/key2')
p2 >>> Path(/key1/key2)
p1 / 'key3' >>> Path(/key1/key3)
p2.parent >>> Path(/key1)
p2.parent == p1 >>> True
'key2' in p2 >>> True
[k for k in p2] >>> ['key1', 'key2']
p2[-1] >>> 'key2'
len(p2) >>> 2
These can be helpful to manipulate paths yourself, as any full access with
a string to a Nob
or NobView
object also accepts a Path
object. So say
you are accessing the keys in list_of_keys
at one position, but that thet also
exist elsewhere in the tree. You could use e.g.:
root = Path('/path/to/root/of/keys')
[t[root / key] for key in list_of_keys]